4 research outputs found
Star-Image Centering with Deep Learning: HST/WFPC2 Images
A Deep Learning (DL) algorithm is built and tested for its ability to
determine centers of star images on HST/WFPC2 exposures, in filters F555W and
F814W. These archival observations hold great potential for proper-motion
studies, but the undersampling in the camera's detectors presents challenges
for conventional centering algorithms. Two exquisite data sets of over 600
exposures of the cluster NGC 104 in these filters are used as a testbed for
training and evaluation of the DL code.
Results indicate a single-measurement standard error of from 8.5 to 11 mpix,
depending on detector and filter.This compares favorably to the mpix
achieved with the customary ``effective PSF'' centering procedure for WFPC2
images. Importantly, pixel-phase error is largely eliminated when using the DL
method. The current tests are limited to the central portion of each detector;
in future studies the DL code will be modified to allow for the known variation
of the PSF across the detectors.Comment: accepted for publication by PAS
Comparison of image restoration algorithms in the context of horizontal-path imaging
We have looked at applying various image restoration techniques used in astronomy to the problem of imaging through horizontal-path turbulence. The input data comes from an imaging test over a 2.5km path. The point-spread function (PSF) is estimated directly from the data and supplied to the deconvolution algorithms. We show the usefulness of using this approach, together with the analytical form of the turbulent PSF due to D. Fried, for reference-less imaging scenarios
Star-image Centering with Deep Learning: HST/WFPC2 Images
A deep learning (DL) algorithm is built and tested for its ability to determine centers of star images in HST/WFPC2 exposures, in filters F555W and F814W. These archival observations hold great potential for proper-motion studies, but the undersampling in the camera’s detectors presents challenges for conventional centering algorithms. Two exquisite data sets of over 600 exposures of the cluster NGC 104 in these filters are used as a testbed for training and evaluating the DL code. Results indicate a single-measurement standard error from 8.5 to 11 mpix, depending on the detector and filter. This compares favorably to the ∼20 mpix achieved with the customary “effective point spread function (PSF)” centering procedure for WFPC2 images. Importantly, the pixel-phase error is largely eliminated when using the DL method. The current tests are limited to the central portion of each detector; in future studies, the DL code will be modified to allow for the known variation of the PSF across the detectors